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- What is Octave?
- Advantages of Octave over others
- Download Octave for your PC
- Useful things to know
- Variables and Data types
- Functions
- Matrices
- Operators
- Strings
- Programming
- Plotting
- Files I/O
- Save your file & load it when needed
What is Octave?
OCTAVE is a high–level language designed for scientific computations. It is most compatible with MATLAB in speed and syntax (to some extent).
Octave can be downloaded from https://www.gnu.org/software/octave/download.html#ms-windows. It features a simple-to-use GUI for scripting files and a command line for instant execution of a line of code. Since it is based on MATLAB, Octave produces M-files, i.e., .m extension files.
It is free open source software under GNU General Public License. It was made for computing linear algebra and matrices. Now, it is used for making machine learning models.
Advantages of Octave over others
There are many other languages for making machine learning models in the market, like Python, Ruby, etc. with many with built-in functions which makes them easier to use. But, one cannot understand the spices inside the functions. Using Octave, we make those spices and can manipulate it as per the requirements.
There are many other advantages of using octave:
- It has C, C++ and FORTRAN as its base languages, which makes it a lot faster.
- Its syntax is very close to mathematical expressions which makes it a good choice for engineers.
- It has high level plot commands for 2D and 3D, for data visualization.
- It supports contour plots.
Download Octave for your PC
1. Go to https://www.gnu.org/software/octave/download.html
2. Download the most compatible version of the octave installer for your PC.
3. Having the process done, install it by following the images (if required).
4. Octave is installed. Now open the Octave CLI.
“Now you are all set to get started.”
In the tutorial, you will get many examples. So, it is advised to practice those by, instead of just copy-paste, typing each letter and try modifying the same. By making mistakes you will get to know many new things. Hope, you will enjoy the tutorial!
Useful Things To Know
It is always better to know about a place before you visit. It helps you not get into trouble or helps you get out of it.
- So, in Octave, maybe the execution of your results into an infinite iteration then you can type ctrl + C to terminate the process. You can terminate any process with this shortcut.
- One-line commenting in Octave either using # or %.
>> % I am a one-line comment
>>
- Block commenting in Octave : #{ …. #} or %{ … %}.
- A line of code is preferred to end with semicolon ‘;’ to stop the instant execution.
- There is one more command that will help you to understand Octave. It is about taking help from Octave by typing help or doc followed by a command about which you wanted to know. This command opens the documentation of the command in the command window or command-line interface (CLI). For instance,
>> help clc % CLC is a command in Octave 'clc' is a built-in function from the file libinterp/corefcn/sysdep.cc -- clc () -- home () Clear the terminal screen and move the cursor to the upper left corner. . . .
You can try these commands: help help, help plot, help isvarname, help size, help inv, help pinv, help reshape, help resize, help round, help cast, help isa, help int8, help logical,
Octave GUI has a documentation window as well where you can find many functions and commands.
To close Octave, type exit or quit.
Variables and Datatypes
Variables are x and y that we have been using since our junior classes. We store values in variables and the type of the value stored is called the Data type of the variable.
Like other programming languages, Octave also provides a simple way to declare variables with the following conditions:
1. It must be a sequence of letters, digits and underscores, not beginning from digits. So, my_var12, my21var_, _var12 and _123var are valid variables but 21my_var is an invalid variables.
2. It should be kept in mind that the Octave is case-sensitive. So, myVar and myvar are treated as different variables.
3. To check the validity of a variable name, there is a function to use: isvarname (‘variable_name’). This returns Boolean value, i.e., true (1) or false (0).
4. Octave has an automatic variable: ans,which appears on pressing “Enter”after writing a line of code.
Octave has some standard built-in data types for real and complex scalars, matrices, ranges, characters, a data structure type, and cell arrays. For example, “scalar”, “matrix”, etc. The function typeinfo (expr) returns the data type of the expr in string form.
As said earlier, Octave works very fast with vectors and matrices. Let’s understand some small but useful terms.
Matrices are a collection of entities in some m rows and n columns. Vectors or arrays are matrices with one column or row. Scalars are matrices with dimension 1 x 1, i.e., a scalar is a single entity matrix. The entities are categorized into integers, characters and logical. Integers are set to “double” by default which has the largest range of numbers. Other values for integers are “int8”, “int16”, “int32”, “int64”, “uint8”, “uint16”, “uint32”, “uint64” and “single”. Characters are single/double quoted characters like ‘ab’, ‘cdac’, ‘1’, etc. while logicals are binary values, i.e., 0 (false) and 1 (true)
To create a matrix, simply type:
>> A = [5 4 -3; 7 -6 4; 9 1 3] A = 5 4 -3 7 -6 4 9 1 3 >>
and Octave responses in clear matrix form.
To create a vector, we just need to replace semicolon inside square braces with spaces.
>> V = [5 4 -3 7 -6 4 9 1 3] V = 5 4 -3 7 -6 4 9 1 3
To create a character string, simply type:
>> myStr = ‘I am a string.’ myStr = I am a string.
Unlike MATLAB, Octave also works the same with double quotes.
To display a declared variable, just type the variable name:
>> a = 23 % a is declared and the value 23 is assigned to it a = 23
To stop the instant output, semicolon ‘;’ is used at the end of the line:
>> a; >> sin(pi); >>
But, if we don’t want to display the name of the variable, then wrap the variable name in disp () function.
>> disp (a) % a is declared and the value 23 is assigned to it 23
The value and data type of a variable are inconstant, i.e, it can be changed whenever required.
>> myVar = 21 myVar = 21 >> myVar = 23 myVar = 23 >> disp (myVar) 23
There are some tricks to know in Octave.
- Command who is used to list the currently defined variables while the command whos gives more detailed list with name, size and class columns.
>> who A V a myStr myVar >>
- We can type the previously typed code by typing the first few letters and scrolling up. It lessens our effort.
- Also, we can scroll up to auto write the earlier codes.
- There are some variables which are mathematical constants used for mathematical uses. Some of those are pi, e, realmin, realmax, eps, I, etc.
>> disp (pi) % displays the value of pi without writing ‘pi’ 3.1416 >> disp (e) 2.7183 >> disp (realmin) 2.2251e-308 >> disp (realmax) 1.7977e+308 >> disp (eps) 2.2204e-16 >> disp(I) 0 + 1i >>
Functions
Functions are like a device which takes some input, processes it and produces output, based on the given input.
We had gone through many functions like isvariable() which takes a variable name and checks it for the validity conditions and finally returns the output. Other functions were size () returns the dimensions of the inputted matrix; strcat ()returns the inputted strings in the same order after concatenation; inv () returns the inverse of a non-singular matrix.
So, there are many built-in functions in Octave to use. But, for the sake of flexibility, in Octave we can define our function as well. For this, we need to create a .m file with the function name as the filename. For instace, let we want to create sum2n () which basically takes one argument and from 1 sums to it, i.e., sum2n (3) should return 6.
Lets create it in the Ocatve’s editor window.
function sum = sum2n (n) sum = n * (n + 1) / 2; endfunction;
The ‘sum’ after function is a variable which will be returned when sum2n (…) is executed.
Let’s see another example.
function [mn mx] = limits (v) % The function limits take a vector v and simply returns the minimum value and maximum value in the vector mn = min (v); mx = max (v); endfunction;
Now, try it in the command window as an exercise. (Hint: You need to assign the function to an 1×2 vector.)
There is another way to create a function instantly. This function is called an anonymous function. Its declaration doesn’t follow the systematic procedure. Also, the anonymous function can be installed into a variable. For the declaration of an anonymous function, the syntax is @ (arguments…) (function…).
>> @ sin (0) % creates a sine function and instantly feed inside it 0 ans = 0 >> f = @ (x) (x*log(x +1)) % the function x*(log(x + 1)) dependent of x installed to variable ‘f’ f = @(x) (x * log (x + 1)) >> f(1) % displays the output of function f of 1 ans = 0.69315 >>
There are many cases when we need to create a function inside a function, in that case as well we use anonymous functions.
It is obvious that the variables declared inside the function are local variables and cannot be accessed from outside the function. However, local variables can be accessed outside the function using the global keyword.
Try searching these functions: any() and all().
Matrices
The base of creating a matrix is illustrated earlier as:
>> A = [5 4 -3; 7 -6 4; 9 1 3] A = 5 4 -3 7 -6 4 9 1 3 >> A = [5, 4, -3; 7, -6, 4; 9, 1, 3] A = 5 4 -3 7 -6 4 9 1 3 >>
As clearly visible, elements in a row are differentiated by a space or ‘,’.
We have some special matrices in Octave. Some are zero matrix, identity matrix, and diagonal matrix.
>> zeros (2, 3) % returns a 2 by 3 matrix having all 0 elements ans = 0 0 0 0 0 0 >> ones (3,2) % returns a 3 by 2 matrix having all 1 elements ans = 1 1 1 1 1 >> eye (3) % returns an identity matrix of order 3 ans = 1 0 0 0 1 0 0 0 1 >> diag ([1 2 3]) % returns a diagonal matrix of order 3 with 1, 2, 3 as diagonal elements ans = 1 0 0 0 2 0 0 0 3 >>
Try magic (4) !
Also, we can install functions in place of numbers. For instance,
>> A = [sin(pi) tan(pi/4) cos(pi/2); acos(-1) atan(1) tan(pi/2); cos(2*pi) sec(2*pi) log(23)] A = 1.2246e-16 1.0000e+00 6.1230e-17 3.1416e+00 7.8540e-01 1.6331e+16 1.0000e+00 1.0000e+00 3.1355e+00 >>
Let’s look at some useful matrix functions.
To add a column and row to a matrix:
>> A = [5 4 -3; 7 -6 4; 9 1 3] A = 5 4 -3 7 -6 4 9 1 3 >> [A, [11; 22; 33]] % Adds a column to matrix A ans = 5 4 -3 11 7 -6 4 22 9 1 3 33 >> [A; [11 22 33]] % Adds a row to matrix A ans = 5 4 -3 7 -6 4 9 1 3 11 22 33 >>
Similarly, more columns and rows can be added.
Remember, indexing in Octave starts from ‘1’ and when extracting elements, always ‘row comes before columns’ followed by further dimensions.
To extract elements from a matrix, syntax matrix_name (index1, index2, …) is used.
>> A = [5 4 -3; 7 -6 4; 9 1 3] A = 5 4 -3 7 -6 4 9 1 3 >> disp (A(1)); disp (A(2)); disp (2, 1) 5 4 4 >> disp (A(2,3)) % display the element at 2nd row and 3rd column of matrix A 4
From the second code in the above example, A(m, n) is the element at mth row and nth column.
To extract all elements from a dimension, row or column, colon ‘:’ is used.
>> A = [5 4 -3; 7 -6 4; 9 1 3] A = 5 4 -3 7 -6 4 9 1 3 >> A(1, : ) % all elements from 1st row ans = 5 4 -3 >> A(:, 2) % all elements from 2nd column ans = 4 -6 1 >>
We can extract a matrix (collections of rows or columns) using colon ‘:’ to delimit the range.
>> A = [5 4 -3; 7 -6 4; 9 1 3] A = 5 4 -3 7 -6 4 9 1 3 >> A(2:3, : ) % matrix all elements from 2nd to 3rd rows ans = 7 -6 4 9 1 3 >> A(:, 1:2) % matrix of all elements from 1st to 2nd columns ans = 5 4 7 -6 9 1 >> A(2:3, 1:2) % matrix of all elements from 2nd to 3rd rows and 1st to 2nd columns ans = 7 -6 9 1 >> A(:, 2:end) % end keyword extracts to the last index ans = 7 -6 4 9 1 3 >>
In almost every case m:n means from m to n.
Defining a range is very easy in Ocatve. It requires syntax start_num : increment(optional) : end_num.
>> range = 1:10 % an array of elements from 1 to 10 is installed in range, i.e., a row vector of 10 elements range = 1 2 3 4 5 6 7 8 9 10 >> range2 = 1:2:10 Range2 = 1 3 5 7 9 >>
Another way for creating a range is linspace () command with syntax linspace (start_num, end_num, no_of_elements).
>> newRange = linspace (1: 10:10) % creates a row vector with 10 elements starting from 1 to 10 newRange = 1 2 3 4 5 6 7 8 9 10 >>
It should be noted that the no_of_elements is not a natural number, a vector with only element 0 is produced.
>> emptyV = linspace (1: 10: 0.1) emptyV = [] (1x0) >> emptyV2 = linspace (1: 10: 0) emptyV2 = [] (1x0) >>
We can assign a value to an element, a row or a column using an assignment operator ‘=’.
>> A = [5 4 -3; 7 -6 4; 9 1 3] A = 5 4 -3 7 -6 4 9 1 3 >> A(1, 2) = -4 % the element at 1st row and 2nd is assigned to -4 A = 5 -4 -3 7 -6 4 9 1 3 >> A(:, 2) = [4; 6; -1] % the 2nd column is assigned A = 5 -4 -3 7 6 4 9 -1 3 >> A(3, : ) = [-9 1 -3] % the 3rd row is assigned A = 5 4 -3 7 -6 4 -9 1 -3 >>
To delete a row or column just assign it an empty matrix [].
>> A = [5 4 -3; 7 -6 4; 9 1 3] A = 5 4 -3 7 -6 4 9 1 3 >> A(2,: ) = [] % the 2nd row is assigned the empty matrix and is deleted A = 5 4 -3 9 1 3 >> newA = [A; [2 4 5; 3 7 1]] newA = 5 4 -3 7 -6 4 9 1 3 2 4 5 3 7 1 >> newA(1:2:5, : ) = [] newA = 7 -6 4 2 4 5 >>
We can know about our matrix through the following commands:
>> A = [5 4 -3; 7 -6 4; 9 1 3; 2 4 5; 3 7 1] A = 5 4 -3 7 -6 4 9 1 3 2 4 5 3 7 1 >> size (A) % returns an two element row vector having no of rows followed by no of columns ans = 5 3 >> no_of_rows = size (A,1) % returns no of rows no_of_rows = 5 >> no_of_columns = size (A,2) % returns no of columns no_of_columns = 3 >> rows (A) % equivalent to size (A,1) ans = 5 >> columns (A) % equivalent to size (A,2) ans = 3 >> [m n] = size (A) % m => no of rows & n => no of columns (good practice) m = 5 n = 3 >> length (A) % returns the max of size (A) ans = 5 >> numel (A) % returns the total no of elements in A ans = 15 >> isempty (A) % returns logical if A is empty(1) or not (0) ans = 0 >> ismatrix (A) % checks for matrix, similar is isvector() ans = 1 >>
Now, let’s look into some of the matrix operations:
Transpose of a matrix is a matrix produced by interchanging rows and columns. In Octave, the transpose of A is A’.
>> A = [5 4 -3; 7 -6 4; 9 1 3; 2 4 5; 3 7 1] A = 5 4 -3 7 -6 4 9 1 3 2 4 5 3 7 1 >> A’ % also transpose (A) ans = 5 7 9 2 3 4 -6 1 4 7 -3 4 3 5 1 >>
Determinant (|A|) is a unique number associated with a square matrix (matrix with equal no of rows and columns). We calculate it using det() function.
>> A = [5 4 -3; 7 -6 4; 9 1 3]; >> det (A) % returns the determinant of A ans = -233 >>
Inverse of a matrix A (A-1) is a matrix such that the matrix multiplication of A and its inverse results into an identity matrix I, i.e., A*A-1 = I. For a matrix to be invertible, it must be singular, i.e, |A| ≠ 0. In Octave, inverse of A is inv (A).
>> A = [5 4 -3; 7 -6 4; 9 1 3] A = 5 4 -3 7 -6 4 9 1 3 >> inv (A) % returns the inverse of A ans = 0.0944206 0.0643777 0.0085837 -0.0643777 -0.1802575 0.1759657 -0.2618026 -0.1330472 0.2489270 >>
However, for non-singular square matrices, there is a pseudo-inverse function pinv () to calculate the inverse.
Operators
Like other programming languages, octave also has operators. Let’s see some of them.
These operators are used for simple mathematical operations.
Arithmetic Operators | |
+ | It is unary operator and binary operator for normal additions. |
– | It is also unary as well as binary operators. |
* | It is scalar and matrix multiplication operator. For instance, two matrices A and B the matrix product is written as A*B. |
/ | It is a right-division operator. For two matrices A and B, A/B is conceptually equivalent to A*inv (A). |
It is a left-division operator. For two matrices A and B, AB is conceptually equivalent to inv (A)*B. | |
^ or ** | It is an exponentiation operator. For a matrix A, A^n is equivalent to A*A*A*…… n times |
Octave supports ‘.’ operator for element-wise operations in case of matrices.
.* | It is an element-wise multiplication operator. |
./ | It is an element-wise right-division operator. |
. | It is an element-wise left-division operator. |
.^ or .** | It is an element-wise exponentiation operator. |
For instance, consider a matrix A = [1 2 3; 4 5 6; 7 8 9]
In Octave, matrix multiplication 🡪 A^2 = [30 36 42; 66 81 96; 102 126 150]
And, element-wise multiplication 🡪 A.^2 = [1 4 9; 16 25 36; 49 64 81]
These are binary operators and returns only 0 and 1 if the result of the operation is false and true respectively.
These operators work on both scalar and non-scalar entities. With arrays, it performs element-wise operations.
Relational Operators | |
== | It is an equal to operator. |
~= | It is a not equal to operator. |
< | It a less than operator. |
<= | It is a less than or equal to operator. |
> | It is a greater than operator. |
>= | It is a greater than or equal to operator. |
These operators take 0s and 1s as arguments and return the binary numbers. Its syntax is :
(expr1) logical_operator (expr2)
For non-scalar exprs’, logical operators returns an of binary numbers.
Logical Operators | |
| | It is an OR operator. It returns 1 if any of expr1 or expr2 is true else returns 0. |
& | It is an AND operator. It returns 1 only if both expr1 and expr2 are true else returns 0. |
! | It is a NEGATION operator. Its syntax is ! (expr). It returns 1 only if expr is false else returns 0. |
Instead of logical operators, there are three functions or (x1, x2, …), and (x1, x2, …), and not (x1).
Other Operators | |
++ | It is an increment operator. It increases the value by unity. |
— | It is a decrement operator. It decreases the value by unity. |
+= | It is a plus-equal to operator. a += 2 is equivalent to a = a + 2. |
-= | It is a minus-equal to operator. a -= 2 is equivalent to a = a – 2. |
*= | It is a multiplication-equal to operator. a *= 2 is equivalent to a = a * 2. |
/= | It is a division-equal to operator. a /= 2 is equivalent to a = a / 2. |
^= | It is a exponentiation-equal to operator. a ^= 2 is equivalent to a = a ^ 2. |
Strings
In Octave, a string is treated as an array of characters. For instance,
>> myStr = ‘I am a string.’ myStr = I am a string >> whos Attr Name Size Bytes Class ==== ==== ==== ===== ===== m 1x14 14 char >> % Some string operations >> myStr (4) % returns the character at index 4 ans = m >> myStr (3:10) % returns the characters from index 3 to 10 in a sequence ans = am a str >> myStr (1: 2: 12) % returns the characters from index 1 to 12 stepping to second character after each character ans = Ia ti >> c = 21; int2str (c) % the function converts integer (21) to string ans = 21 >> d = 23.98674; num2int (d) % the function converts the number to string ans = 23.98674 >> num2int (d, 5) % the function converts the number to string and prints first 5 characters ans = 23.986 >> strcat (mystr(1: 7), ‘concatenated’, mystr(7:end)) ans = I am a concatenated string >>
There are more functions that you can search in Octave using the help command. Try searching these functions:
strjust(), str2num(), tolower(), toupper().
Programming
So far, we have been seeing Octave as a calculator. Now, we will try to use it as a programming language using some decision making statements, for and while loops, etc.
Decision-Making Statements
If statement executes the code inside it if the condition given to it is true.
>> age = 14; >> if (age < 16), disp(‘You are below 16 yrs.’); endif; You are below 16 yrs. >>
If-elseif statement executes the code instantly if the condition above it is true.
>> age = 14; >> if (age < 12), disp(‘You are under 12’); elseif (age < 18), disp(‘You are a teen.’); else disp(‘You are above 18.’) end You are a teen. >>
*There is no limit in using elseif conditions.
Switch statement is case-specific, i.e., only that line of code will be executed whose case label satisfies the switch condition.
>> age = 12; >> switch (age), % age is set to 12 case 5 disp(‘You are 5 yrs old.’); case 12 disp(‘You are 12 yrs old.’); case 18 disp(‘You are 18 yrs old.’) otherwise disp(‘You are an adult.’) end You are 12 yrs old. >>
Iterative Loops
do-until loop iterates until the until condition not fulfilled. Its syntax is do, body; until (condition) which seems really easy to understand like ‘iterate the body till the until condition is not reached’. In the below example, we will create the loop to get the factorial of a number.
>> fact = 1; i = 1; % variables fact and i is initialized to 1 >> do % initializes the do-until loop i++; % increases the variable I by unity until it fulfills the until condition fact *= i; % similar to fact = fact * i ; excutes until i fulfills the until condition until (i == 5) % ends the do-until loop after declaring the until condition. >> fact % installs the current value of ‘fact’ to the Octave variable ans ans = 120 >>
while statement iterates till the conditions holds true. For example,
>> i = 0; % variable i is initialized to 0 >> while i<10, % initializes the while loop by declaring while-condition i++; % increments i each time till it fulfils the while-condition i % prints the value in i endwhile i = 1 i = 2 i = 3 i = 4 >>
for statement iterates the code untill the expression completes. For example,
>> for i = 1:10, % initializes the for loop and the variable i, feed it value from 1 to 10 in each iteration i % prints i in each iteration endfor i = 2 i = 3 i = 4 i = 5 i = 6 i = 7 i = 8 i = 9 i = 10 i = 11 >>
To interrupt a loop, break keyword to get out of the loop (for or while) while to skip the rest of the body continue keyword is used.
In speed, the for and while loops are almost the same. So, use that one which is easier to use.
To know the time taken by Octave to execute the whole loop, use tic–tac command. Write tic above and tac below the loop. For instance,
>> i = 0; % variable i is initialized to 0 >> tic, while i<10, % tic initializes the time to 0 seconds i++; % increments i each time till it fulfils the while-condition i % prints the value in i endwhile, toc % toc returns the time taken to execute the while loop from time = 0 seconds Elapsed time is 1.7881e-05 seconds. >>
Note, the time shown to me may vary to you for the same code. It time it outputs is based on your system.
Plotting
Octave provides an interactive graph. This graph is invoked using plot() function which requires two arrays as arguments. For instance,
>> x = -10:0.1:10; >> plot(x, sin (x)) % plots the ‘x’ in x-axis and sin of x in y-axis >>
The execution invokes the following figure:
Some useful commands in Octave for plottings:
clear all | It clears all opened figures. |
grid on | It shows grid on the plot. |
grid off | It shows no grid on the plot. It is the default situation. |
axis ([…]) | It delimits the axes. It takes a vector containing 4 elements, first two are the range of x-axis and the other two are the range of y-axis. |
title (‘…’) | It sets the title of the plot. |
xlabel (‘…’) | It sets the x-label, i.e., the name of x-axis on the plot. |
ylabel (‘…’) | It sets the y-label, i.e., the name of y-axis on the plot. |
legend (‘…’) | The legend is the name the line/curve in the graph. The function sets it and displays it on the plot. We can decide the position of legend by giving attribute ‘location’ to legend (“location”, ‘north’). |
Let’s use the above commands to plot a meaningful sin function.
>> x = -10:0.1:10; % creates a vector with numbers from -10 to 10 with difference 0.1 >> y = sin (x); % creates a vector containing the sin of each number in ‘x’ >> plot (x, y); % creates a figure showing the x-y graph and displays the below image >> grid on; % shows the plot on grid >> axis ([ -10 10 -1 1]); % delimits the axes >> title (‘sin function’); %sets title to the graph >> xlabel (‘x’); % sets x-label to ‘x’ >> ylabel (‘sin (x)’); % sets y-label to ‘sin (x)’ >> legend (‘sin’); % sets legend to ‘sin’ >> legend (‘location’, ‘north’); % locates the legend at center and top >>
We can make this plot more beautiful by adding some color or by increasing the line-width. For more clarity, type the command help plot.
We can use fplot () for making graph of functions. Using fplot () is a faster way of plotting which takes the function and the limits (in a vector form) as arguments.
>> fplot (@sin, [-10 10]); % creates the graph of sin function from -10 to 10 >> grid on; % shows the plot on grid >> title (‘sin function’); %sets title to the graph >> xlabel (‘x’); % sets x-label to ‘x’ >> ylabel (‘sin (x)’); % sets y-label to ‘sin (x)’ >> legend (‘sin’); % sets legend to ‘sin’ >> legend (‘location’, ‘north’); % locates the legend at center and top >>
We can load a figure to a variable, say h, just by assigning it to h. The h is called graphics handle. It is a pointer to denote a figure by assigning each figure a unique number. For instance,
>> gh = figure (); % creates a graphics handle ‘gh’ >> fplot (@sin, [-3 3]) >> gh % prints the value inside the graphics handle ‘gh’ ans = 1 >> get (h, ‘type’) % get () function prints property, here ‘type’, of the handle given to it ans = figure >>
Let’s see some manipulative commands.
hold on | It holds the current plot and let the next plot (s) to superimpose on it. |
hold off | It releases the plot from the hold state. |
subplot () | It shows two or more plots in one figure. The plots order are managed in a matrix form.This will be illustrated later. |
Time to apply!
>> fplot(@sin, [-5 5]); >> xlabel (‘x’); ylabel (‘f (x)’); >> hold on; % holds the plot for addition of the following plot >> fplot (@cos, [-5 5]); >> legend (‘sin’, ‘cos’); % sets legend to the plots in order >> title (‘sine-cosine waves on the same plot’); >>
Look at the subplot () function.
>> subplot (2, 1, 1) % creates a figure having two subplots in 2 x 1 matrix form, the third argument is the index of the subplot >> fplot (@sin, [-5 5]) ; % plots the graph on the first subplot >> xlabel (‘x’); ylabel (‘sin (x)’) % sets x-y labels >> legend (‘sin’, ‘location’, ‘northwest’); % sets legend to ‘sin’ and locates it at top and left of the subplot >> title (‘sine wave’); % sets title to ‘sine wave’ >> subplot (2, 1, 2) % creates the second subplots >> fplot (@cos, [-5 5]); % plots the graph on the second subplot >> xplot (‘x’); ylabel (‘cos (x)’) % sets x-y label >> legend (‘cos’, ‘location’, ‘northwest’) % sets legend to ‘cos’ and locates it at top and left of the subplot >>
Now, we have made many figures. It’s time to save it. Octave provides some formats to save the graphics.
Some useful formats are jpg, jpeg, png for images and others are pdf, however the default ps format. Its syntax is saveas (graphics_handle, ‘file_name’, ‘options’). We can set format inside options. For instance,
>> gh = figure (); % creates a graphics handle >> fplot (@sin, [-3 3]); % plot sine function >> xlabel (‘x’); ylabel (‘sin (x)’); % sets x-y labels >> title (‘Sine Wave’); % sets title >> saveas (gh, ‘sine wave’, ‘jpg’); % save the figure in the current directory with name ‘sine wave’ in ‘jpg’ format >>
You should see the following jpg image in the directory.
Try other formats that suit you.
Files I/O
Now, we will see some useful system commands on Octave. These commands are inherited from UNIX.
Let’s see some of them.
cd ‘path’ | It stands for change directory. It changes the directory to the path given to it. |
chdir ‘newdir’ | It changes directory to newdir |
mkdir ‘newdir’ | It creates directory and names it newdir. |
diary | It records the commands executed and the output they produce. It wakes up when switching it to on (>> diary on) and sleeps when switch it to off (>> diary off) while when no arguments is given sustains the current state. |
Date | It is used to display the present date. |
delete | It is used to delete a file. |
dir | It is used to list all the files in the present directory. |
pwd | It stands for present working directory. It is used to display the current directory. |
type | It is used to display contents of a file. |
what | It is used to list all .m files, i.e., Octave and MATLAB files. |
Practice it. This increases your interaction with the system.
Save your file & Load it when needed
Octave CLI (command line interface) saves our file in our desired path using save … command. For instance,
>> save myfile % saves myfile to the current directory >> save desiredPathmyOctaveFilesmyfile1 % saves myfile1 to the myOctaveFiles
Files are loaded also in Octave CLI using load …. command. For instance,
>> load myfile % loads myfile >> load desiredPathmyOctaveFilesmyfile1 % loads myfile1
using load command we can also load data in .txt format.
This brings us to the end of the blog on Octave Tutorial. We hope that you found this helpful and were able to learn more about the concepts. If you wish to learn more such skills, join Great Learning Academy’s pool of Free Online Courses!
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